Method of and apparatus for processing a video image

ABSTRACT

A color enhancement method for use in a video camera imaging system in the context of non-uniform lighting includes an adaptive algorithm for developing a shutter speed control signal, analog gain control signal and color balance signals from pixel luminance over one field of video. The control signals developed during one field are used to control the camera during the next field. The speed control signal and analog signal are determined based on the luminance signal obtained in digital form from the video camera, and analyzed over at least one field of video.

CROSS REFERENCE TO RELATED APPLICATIONS

This patent application is a Divisional of, and claims priority to under35 U.S.C. §120, U.S. patent application Ser. No. 09/438,406, filed onNov. 12, 1999, now U.S. Pat. No. 6,930,710 entitled, “A Method Of AndApparatus For Processing A Video Image” and having Brian J. Classen andJordan C. Christoff as the Inventors. The full disclosure of U.S. patentapplication Ser. No. 09/438,406 is hereby fully incorporated byreference.

FIELD OF THE INVENTION

The present invention relates to a method and apparatus for adjustingthe contrast of a video image in a color video camera. Moreparticularly, the invention provides for contrast adjustment with colorgain adjustment in each filed of video so that consistent hue values aremaintained between fields and the resulting image more closelyapproximates the dynamic range of the human eye.

BACKGROUND OF THE INVENTION

A Variety of discrimination systems, operating in a range ofcircumstances, use color analysis as a basic tool. An example can befound in agriculture, where a green area, such as a weed or other targetplant, is to be detected within an area of another color, such as brownsoil, in order to be sprayed. However, plant material on the ground,under natural, outdoor conditions, is not easily detected based on colordetection if the detection equipment is a conventional video camera. Thetrue color (hue) and brightness of objects may be altered in the videoimage, depending on the prevailing light level and on whether the objectis in direct sunlight or in dark shade.

Color, as perceived by the human eye, can be described in terms of thethree components lightness, hue and saturation as illustrated in FIG. 1.

Lightness L * is the perceptual human response to luminance Y, a CIE(Commission Internationale de L'Eclairage) quantity, defined as theradiant power weighted by a spectral sensitivity function that ischaracteristic of vision. Roughly speaking, areas appearing brighterthat emit more light, have higher luminance Y. Lightness L * is relatedto luminance Y through the formulaL *=116(Y/Y _(n))^(1/3)−16; 0.008856<Y/Y_(n)where Y_(n) is the luminance of the white reference. Therefore, inpractice, one can work with either quantity. In the 3-dimensional colorspace illustrated in FIG. 1, lightness L * varies from black to white.

Saturation is the colorfulness of an area judged in proportion to itsluminance. Roughly speaking, the more the spectral power distribution(SPD) of a light source is concentrated at one wavelength, the moresaturates will be the associated color. A color can be desaturated byadding light that contains power at all wavelengths. In FIG. 1,saturation is the length of the vector extending from the vertical axis.

HUE is the attribute of visual sensation according to which an areaappears to be similar to one of the perceived colors, red, yellow, greenand blue, of a combination of two of them. Roughly speaking, if thedominant wavelength of the SPD shifts, the hue of the associated colorwill shift. In FIG. 1, the hue is determined by the angle of the vector.

When capturing images, cameras can have their exposure and color balancesettings adjusted. The exposure is adjusted in order to achieve adesired level of luminance. The color balance is adjusted so that thecolors in the image are at their desired hues.

In the case of a video camera using a charge coupled device (CCD) as theimage sensor, the exposure may be adjusted by adjusting the shutterspeed and/or the analog gain. Shutter speed refers to the amount of timewhich the image sensor is exposed to the image. In a typical CCDapplication, the shutter speed is controlled electronically bycontrolling the number of overflow drain pulses (OFD) applied to thesensor to discharge the accumulated charge in the individual CCD pixelsites.

Analog gain refers to the gain of the analog amplifier immediately afterthe CCD. The signal output from a CCD is an analog signal; comprising ofa reference voltage and a readout voltage for each pixel site. The firststage of processing the video signal output from the sensor is todetermine the difference between the reference and readout voltage, andthen amplify the difference signal for subsequent processing.

By adjusting the settings for shutter speed and analog gain, theluminance level of pixels in the output signal can be brought in a rangeoptimum for signal processing. The absolute values of the luminancevoltage levels at specific colors and intensities are defined byinternational standard. To ensure accurate signal processing, it isdesired to maintain the luminance levels in the midrange of a workablerange having an upper limit Max Level (FIG. 6A) and a lower limit MinLevel so that noise at a low levels and overflow at high levels does notinterfere with the processing.

The color balance is adjusted by adjusting the color gains in thedigital signal processor (DSP) of a conventional camera. The color gainsare adjusted at their desired levels so that the overall image color,when viewed on a vector scope, is centered around white.

Consider the case where a scene is illuminated with a steady lightsource and the scene is captured by a conventional color camera with twodifferent shutter speeds. Two slightly different images are obtained.The luminance levels of the two images are different since they werecaptured with different shutter speeds. The saturation levels of the twoimages are also different, as saturation depends on lightness, and thuson luminance. However, the hues of the colors in both images should beidentical, since the color makeup, the SPD, of the two images is thesame, as determined by the steady light source.

Consider now the case were two images of a scene are captured using adifferent light source for each image, but the same shutter speed andcolor gain settings in the camera are maintained. The two images aredifferent as the luminance and saturation levels are different. Inaddition, the hues are different in the two images because the colormakeup of the incident light is different is each case, and the samecolor gain settings have been used for each image.

A standard approach to adjusting the video image to the scene beingcaptured is to adjust the shutter speed of the CCD, and to adjust theanalog gain of the CCD output signal, so that the analog output signalis within a desired range of operation. In situations where there is alarge contrast between the darkest and brightest areas, the resultingimage will either have areas which appear darker in the video image thanthey actually are, or areas which appear overexposed and brighter thanthey actually are.

There are prior art video camera systems that try to compensate fornon-uniform lighting. Some of these systems use adaptive exposurealgorithms that determine two different shutter speeds and/or analoggain settings, for alternating fields of video, targeting bright areasand dark areas, respectively. Typically, these video camera systems usethe same color gain settings for each field of video. As a result, thehue values between alternating fields of video are inconsistent.

SUMMARY OF THE INVENTION

An object of the present invention to provide a technique for enhancingthe color information in a video image of a scene while adjusting thecontrast of the image, the scene being illuminated with varying orno-uniform lighting.

According to the present invention, there is provided a method forprocessing a video image in a video camera having exposure and colorbalance adjustment means, the method comprising the step of adjustingthe exposure and color balance settings on alternate fields of video.

A further object of the invention is to provide a method of, andapparatus for, processing a video image in a video camera having shutterspeed, analog gain and color balance adjustments means, the methodcomprising the steps of: a) obtaining a luminance signal from the videocamera, in a digital format; b) analyzing the luminance signal over afirst field of video; c) determining, based on the analyzed luminancesignal , a first set of control signals including a first shutter speedcontrol signal and a first analog gain signal, the first set of controlsignals causing the luminance of a majority of pixels in a field videoto be below a first limit defining a workable range of luminance; d)determining, from the first set of control signals, a first set of colorbalance settings; e) during a second field of video, applying the firstshutter speed control signal, the first analog gain signal and the firstset of color balance settings to the shutter speed, analog gain andcolor balance adjustment means, respectively; f) analyzing the luminancesignal over the second field of video; g) determining, based on theanalyzed luminance signal, a second set of control signals including ashutter speed control signal and a second analog gain signal, the secondset of control signals casing the luminance of a majority of pixels in afield video to be above a second limit defining the workable range ofluminance; h) determining, from the second set of control signals, asecond set of color balance settings; and, i) during the next field ofvideo, applying the second shutter speed control signal, the secondanalog gain signal and the second set of color balance settings to theshutter speed, analog gain and color balance adjustment means,respectively.

According to the method the invention the color information from a videoimage of a scene with non-uniform lighting is enhanced us an adaptivealgorithm providing variable sets of adjusting values for setting theexposure and color balance settings of the camera on succeeding fieldsof video. The settings for one field are determined based on theluminance signal analyzed over the preceding field of video. One set ofsettings targets dark areas of image and the other set targets thebright areas of the image. The two sets are used on alternate fields ofvideo so that over two fields a pixel has the correct color informationin at least one field. Every pixel is within the workable range ofluminance in at least one field, over the two fields, due to theexposure settings. Furthermore, consistent hue values are maintainedbetween alternate fields, as the color balance settings for the fieldsare adjusted according to the exposure settings, thus to the luminancelevel for each field.

In one embodiment, an apparatus according to the invention comprises acolor video camera, a histogram counter for examining the luminanceoutput signal of the camera over a field of video, a pixel colordetection circuit, and a micro controller responsive to the histogramcounter for generating sets of exposure control and color balancesignals that are applied to the camera and color offset signals that areapplied to the pixel color detection circuit. The pixel color detectioncircuit may include means for identifying pixels of color correspondingto a color region of interest. In a second embodiment of the invention,the histogram counter, and at least a portion of the pixel colordetection circuit comprise circuits within a conventional video camera.

According to a further aspect of the invention, a pixel color detectioncircuit examines each pixel of a video image to determine whether it isin color region of interest. The pixel color detection circuit uses acolor offset signal, calculated by a controller based on the luminancesignal. The color offset signal indicates how far from neutral, orwhite, in the chosen color space, is the chrominance data from thecamera.

The invention may be used to advantage on agricultural sprayers having avideo camera for detecting green weeds which are then sprayed withchemicals from nozzles disposed near the camera.

Other objects, advantages and features of the invention will be readilyapparent to those skilled in the art upon consideration of the followingdetailed description and the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a description of the organization of color-perception space incylindrical coordinates, in terms of hue, lightness and saturation;

FIG. 2 is a block diagram of a system in accordance with one embodimentof the invention.

FIG. 3 is a block diagram of a system in accordance with anotherembodiment of the invention and illustrating major components of thevideo camera shown in FIG. 1;

FIG. 4 is a block diagram of circuits contained within the digitalsignal processor shown in FIG. 3;

FIG. 5 is a flow diagram illustrating the steps of a method inaccordance with the present invention;

FIGS. 6A and 6B are waveform diagrams illustrating adjustment of a videosignal on alternate video fields to bring the majority of pixelluminance values below the upper limit of a workable range; and,

FIGS. 6C and 6D are waveform diagrams illustrating adjustment of a videosignal on alternate video fields to bring the majority of pixelluminance values above the lower limit of a workable range.

FIGS. 7 a block diagram of system and controller with nozzles.

DETAILED DESCRIPTION OF THE INVENTION

Referring to FIG. 2, a video system 10 according to the inventioncomprises a CCD color video camera 12, a histogram counter 14, a microcontroller 16 and a pixel color detection circuit 18.

Camera 12 is a well-known Sony camera and will first be described toprovide background for understanding the invention. As shown in FIG. 3,camera 12 comprises a lens 20 for imaging a scene on a Charge CoupledDevice (CCD) sensor 22, a timing control and driver circuit 23, aCorrelated Double Sampling and Analog gain Control circuit (CDS/AGC) 24,an analog to digital converter (ADC) 25, and a Digital Signal Processor(DSP)26. For clarity in explaining the invention, a micro controller 27is shown separately in FIG. 3 but in actual practice this microcontroller in implemented within DSP 26 as shown in FIG. 4.

Timing control and driver circuit 23 may be a model CXD2408R chipcommercially available from Sony Corporation. Circuit 23, in response tocommands from micro controller 27, sets the camera exposure or shutterspeed by controlling the duration of overflow drain pulses applied tosensor 22 and also controls the readout from the sensor. The analogvideo output from sensor 22 is applied to CDS/AGC circuit 24 which maybe a Sony model CXA2006Q chip. the processed and gain controlled analogoutput signal form CDS/AGC 24 is then applied to the ADC 25. ADC 25converts the analog signal into 8-bit digital video signals, each signalcorresponding to a pixel position on sensor 22.

The output signals from ADC 25 are applied to DSP 26 which may be a Sonymodel CXD2163R digital signal processor chip. As shown in FIG. 4, DSP 26includes luminance (Y) processing circuits 32, chrominance processingcircuits 34, and a histogram counter 36, in addition to the microcontroller 27.

The chrominance processing circuits 34 include a low pass filter andclamp circuit 38, a red/green/blue (RGB) matrix 40, white balance (WB)circuit 42, a gamma correction circuit 44 and a transformation matrix46. A DSP bus 48 connects micro controller 27 to the Y processingcircuits 32, histogram counter 36 and various components within thechrominance processing circuits 34 so that the micro controller maycontrol various functions performed within the DSP.

Briefly, the digital video output of ADC 25 is applied via path 52 tothe luminance processing circuit 32 and the chrominance processingcircuit 34. The luminance processing circuit produces the luminancesignal Y which is available at an output port 54. In the chrominanceprocessing circuit 34, the video signal is applied to the low passfilter and clamp circuit 38 having an output connected to the RGB matrix40. This matrix transforms the video signal into luminance and red,green, and blue component values or signals. After processing in whitebalance circuit 42 and gamma correction circuit 44, the signals areapplied to a transformation matrix which transforms the signals intocolor difference signals B-Y (orU0 and R-Y (or V) which are available atan output port 56. The matrix 46 produces one digital color differencesignal (U or V) concurrently with each digital luminance signal Yproduced by luminance processing circuit 32, the color differencesignals alternating between U and V.

Returning now to FIG. 2, the luminance signal Y produced by DSP 26 inFIG. 4 is applied a histogram counter 14 for analysis. The histogramcounter 14 has an ‘over-limit’ bin and an ‘under-limit’ bin programmableby controller 16 to count pixels having luminance over or underrespective luminance thresholds set by controller 16 and defining theworkable luminance range. The bins are used alternately. One bin is usedto count the number of pixels in a first field of video having aluminance above a first threshold or high limit and the other bin isused during the next field of video to count the number of pixels havinga luminance below a second threshold or low limit. A field of video isdefined as the capture of one vertical cycle of the CCD sensor in thevideo camera.

The histogram bin counts produced by histogram counter 14 are utilizedby controller 16 to develop two sets of camera control signals, S_(A)and S_(B) designed to bring the luminance of as many pixels as possible(about 90% in actual practice) within the workable luminance range. Eachset of control signals includes a shutter speed control signal and ananalog gain setting signal. These signals are transferred to the cameramicro controller 27 (FIG. 3) which in turn controls the timing andshutter speed control circuit 23 and analog gain circuit 24 withincamera 12. The signals of set S_(A) are intended to keep the majority ofpixel values above the minimum level of the workable range of luminancewhereas the signal of set S_(B) are intended to keep the majority ofpixels below the maximum level of the workable range of luminance.

The method of color enhancement according to the invention isillustrated in FIG. 5. At step 100 the analog video signal is processedover a field of video to develop a digital luminance signal Y for eachpixel of a field. At step 101 the over-limit bin of the histogramcounter counts the number of pixels in a first field having a luminancegreater than Max Level as illustrated in FIG. 6A. At the end of thefirst field, controller 16 samples the over-limit bin count and develops(at step 102) the set of control signals S_(A).

At step 103 a set of color gain signals C_(A) are developed, as laterexplained, from the set of signals S_(A).

At step 104, the sets of signals S_(A) and C_(A) are applied to thecamera to control shutter speed, analog gain and color gain during asecond field of video. During the second field, the set of signals S_(A)control the camera to bring the luminance of most pixels below the maxlevel, as shown in FIG. 6B.

The analog video signal for the second field is processed at step 105 todevelop a digital luminance signal Y for each pixel and during thesecond field the under-limit bin of the histogram counter counts(step106) the number of pixels having a luminance less than Min Level shownin FIG. 6C. At the end of the second field the controller 16 samples theunder-limit bin count and develops (at step 107) the set of controlssignals S_(B) which are utilized to control the camera during the nextvideo field.

Step 108 develops a second set of color gain signals C_(B). At step 109,the sets of signals S_(B) and C_(B) are applied to the camera to controlthe shutter speed, analog gain and color gain during the next field. Thesignals S_(B) control the shutter speed and analog gain to bring theluminance of most pixels above the min level as shown in FIG. 6D.

Steps 100-109 are then repeated (step 110) so that over any twoconsecutive fields of video the luminance of most of the pixels isbrought within the workable range in at least one of the two fields. Onefield is optimal for the darker areas of an image and the other field isoptimal for the brighter areas. Furthermore, because the color gainsettings are adjusted according to the luminance level for each field, aconsistent hue value is maintained between the two fields. By combiningthe information in the alternate fields, the true color of each pixel inthe image can be more accurately determined.

As mentioned above, controller 16 also alternately generates a set ofcolor gain signals C_(A) based on the signals of set S_(A) or a set ofcolor gain signals C_(B) based on the signals of set S_(B). The colorgain signals C_(A) or C_(B) are transmitted to camera micro controller27 (FIG. 3) with the sets of signals S_(A) or S_(B), respectively.Within the camera, micro controller 27 utilizes the color gain signalsto set color gains within the white balance circuit 42 (FIG. 4). Alook-up table may be used to determine the color gain signal values foreach set of shutter speed and analog gain settings.

The controller 16 also generates a color offset signal for use by thepixel color detection circuit 18. The color offset signal indicates tothe pixel color detection circuit 18 how far away from the neutral, inthe chosen color space, is the chrominance data U/V produced by thematrix 46 (FIG. 4). At different color temperatures of incident light,the chrominance data U/V from the camera 14 varies with respect to itsneutral, or white position and the color offset signal providescompensation for this effect. The controller 16 has therein a luminanceintegrator and a table of color offset values (not shown).The luminancesignal is integrated over one field and used to develop and address foraddressing the table to obtain the color offset signal which is relayedto the color detection circuit 18 in the interval between successivefields. One method of determining the color offset signal based on thetotal luminance is to use a linear equation, y=mx+b, where the y is thecolor offset original, x is the total luminance, and m and b areexperimentally determined based on the color region of interest. Thevalues are implementation dependent. In another method, a look up tablecould be used instead of the equation. Other methods may be used.

The pixel color detection circuit 18 examines each pixel signal from thecamera 12 to determine whether the pixel is in the color region ofinterest. The following scenario is provided as an example. Considerthat one needs to identify all blue pixels. In the UV color space shownin FIG. 1, blue can be approximated as the region defined by U>0 andV<0, where 0 falls on the lightness axis. This holds true when the colorgain in the camera is perfectly tuned to match the incident light colortemperature and white is in the centre of the space, i.e. it isrepresented by U=0 and V=0. The color offset signal from the controller16 is used to compensate for the case where the color gain is notperfectly matched. The color offset signal is represented by its twocomponents in the UV space, blue_offset and red_offset. The blue regionis defined by U>blue_offset and V<red_offset. Using this equation, thepixel color detection circuit 18 can detect the blue pixels in a fieldvideo.

Our concurrently filed application referenced above describes in detaildifferent embodiments of the pixel color detection circuit 18 and how itis utilized to detect green weeds for the purpose of spraying them witha chemical agent. In its simplest embodiment, circuit 18 comprises gaincircuits for maximizing the color difference signal U or V in the colorregion of interest while minimizing all other signals. For example,since green is defined by negative values of V are maximized in order todetect green weeds. In other words, the gain of the color differencesignal V is maximized for quadrants III and IV ( FIG. 1) and minimizedfor quadrants I and II, the color difference signal U being minimizedfor all quadrants. The negative values of V are then comprised to athreshold value to determine if the value of V is negative enough to beconsidered green.

An operator may select, via controller a particular color of pixels tobe detected. Depending on the color selected, the controller selects athreshold value, for example, the negative value the V axis signal musthave to be considered green. This threshold value is modified by thecolor offset signal (red_offset when green pixels are being detected)and the resulting value is used as the threshold which is compared tonegative signals to determine if pixels are green.

Since the hue vector (see FIG. 1) for green is actually displacedapproximately 30° from the negative V axis toward the negative U axis,circuit 18 may, in some embodiments, include a transformation circuitfor rotating the color difference signals U counterclockwiseapproximately 30° so that the green information in the U signals mayalso be used to more accurately detect green pixels.

In FIG. 2, the histogram counter 14, controller 16 and pixel colordetection circuit 18 are all external of the video camera. The videocamera shown in FIGS. 3 and 4 includes circuits permitting some of thefunctions of controller 16 using the histogram counter 36. Thetransformation matrix 46 includes gain circuits controllable by microcontroller 27 hence the function of maximizing of the negative V signalmay done in matrix 46 rather than in pixel color detection circuit 18.The matrix 46 is also controllable by micro controller 27 to rotate thecolor difference signals so the function of rotating the colordifference signal approximately 30° may also be performed in the matrixrather than in circuit 18.

the function of comparing the maximized negative V signal with athreshold to determine if it is green cannot be performed in the camera12 so a pixel color detector circuit 28 is provided to perform thisfunction. A micro controller 60, connected to the camera microcontroller 27 by a conventional interface circuit (not shown) is stillrequired to permit operator entry of the pixel color interest.

FIG. 5 illustrates an application of the present invention toagricultural sprayers and more particularly to weed detection spraying.The output of system 30 (FIG. 5), specifically the output of the pixelcolor detection circuit 28, is connected to a nozzle micro controller64. Detection circuit 28 is a programmable logic array. In addition tocomparing for target color (green) circuit 28 counts the umber of pixelsof the target color occurring on each video scan line. Spray controller64 samples the outputs from section circuit 28 for the purpose ofcontrolling two spray nozzles 68 and 70.

Controller 64 also receives data via a CAN bus 74. This informationincludes a nozzle turn-on time, a nozzle turn-off time and a thresholdvalue (weed size) representing the minimum number of green pixels perscan line, per region, that must be detected in order to actuate a spraynozzle. In this regard, a sprayer may spray a path having a width of 30feet or more, is provided with a plurality of cameras. Each camera isaimed do as to view a different portion of the path to be sprayed. Thefield of view of each camera is divided into two regions and two nozzles68, 70 are provided for spraying a respective region. Controller 64utilizes the green/not green signal from detector circuit 28 todetermine, for each scan line, how many green pixels have been detectedwithin each region. If the number of green pixels within a regionexceeds the threshold value (weed size) input by an operator via CAN bus74, then the controller 64 produces a signal to activate the nozzle forthat region when the nozzle is over the detected weed.

The camera is in front of the nozzles ad a nozzle is turned on only whenit is over a weed. Circuits (not shown) measure the forward progress ofthe sprayer and develop turn-on and turn-off times based on the progressof the sprayer and the camera to the nozzle distance.

It will be understood that a keyboard or control panel is linked to CANbus 74 permit an operator to enter the threshold value defining weedsize. Operator selection of the color pixels to be detected is enteredvia the same keyboard and is relayed to controller 72 via controller 64and a serial communication circuit 66.

The functions of controllers 60 and 64 may be carried out in a singlemicro controller rather than two. Numerous other modifications,variation and adaptations may be made to the particular embodiments ofthe invention described above without departing from the scope of theinvention, which is defined in the claims.

1. A method of processing a video image in a video camera havingexposure and color balance adjustment means, the method comprising thestep of: providing a variable set of adjusting values for setting theexposure and color balance settings of the camera on succeeding fieldsof video; analyzing the settings for one field based on luminance signalfrom a preceeding field of video; adjusting the exposure settings onalternate fields of video, so that one set of settings on field targetsobjects in dark areas of the image and an alternate set of field targetsobjects in bright areas of the image; providing the set of setting onfield targets objects in dark areas and the alternate set of fieldtargets objects in the bright areas of the image are maintained onalternate fields of video wherein that over two fields a pixel has thecorrect color information in at least one field; and, adjusting thecolor balance for each field based on the exposure setting for thatfield.
 2. A method of processing a video image signal in a color videocamera having shutter speed and exposure and analog gain and colorbalance adjustment means, the method comprising the steps of: a)deriving a digital luminance signal for said analog video image signal;b) analyzing the luminance signal over a first field of video; c)determining, based on the analyzed luminance signal, a first set ofcontrol signals including a first shutter speed control signal and afirst analog gain signal, the first set of control signals causing theluminance of a majority of pixels in a field video to be below a firstlimit defining a workable range of luminance, d) determining, from thefirst set of control signals, a first set of color balance settings; e)during a second field of video, applying the first shutter speed controlsignal, the first analog gain signal and the first set of color balancesettings to the shutter speed, analog gain and color balance adjustmentmeans, respectively; f) analyzing the luminance signal over the secondfield of video; g) determining, based on the analyzed luminance signal,a second set of control signals including a second shutter speed controlsignal and a second analog gain signal, the second set of controlsignals causing the luminance of a majority of pixels in a field ofvideo to be above a second limit defining the workable range ofluminance; h) determining, from the second set of control signals, asecond set of color balance settings; i) during the next field of video,applying the second shutter speed control signal, the second analog gainsignal and the second set of color balance settings to the shutterspeed, analog gain and color balance adjustment means, respectively; j)providing a variable set of adjusting values for setting the exposureand color balance settings of the camera on succeeding fields of video;k) analyzing the settings for one field based on luminance signal from apreceeding field of video; l) adjusting the exposure settings onalternate fields of video, so that one set of settings on field targetsobjects in dark areas of the image and an alternate set of field targetsobjects in bright areas of the image; m) providing the set of setting onfield targets objects in dark areas and the alternate set of fieldtargets objects in the bright areas of the image are maintained onalternate fields of video wherein that over two fields a pixel has thecorrect color information in at least one field; and, n) adjusting thecolor balance for each field based on the exposure setting for thatfield.